Métodos y Materiales ISSN Impreso: 2215-342X ISSN electrónico: 2215-4558

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Comparison of Mechanical Properties of Deformed Steel Wire Determined using Contact and Laser Extensometers
Vol. 4 (2014), Articles
Vol. 4 (2014)

Comparison of Mechanical Properties of Deformed Steel Wire Determined using Contact and Laser Extensometers

Articles
https://doi.org/10.15517/mym.v4i1.21110
Ana Lorena Monge Sandí
LanammeUCR
Ana María Rodríguez Pereira
Instituto Tecnológico de Costa Rica
PDF (Español (España))

Keywords

Extensómetro axial
Extensómetro láser
Esfuerzo de fluencia
Alambre para refuerzo
Conventional Extensometers
Laser Extensometer
Yield Strength
Reinforcement Wire

How to Cite

Monge Sandí, A. L., & Rodríguez Pereira, A. M. (2014). Comparison of Mechanical Properties of Deformed Steel Wire Determined using Contact and Laser Extensometers. Métodos Y Materiales, 4(1), 24–32. https://doi.org/10.15517/mym.v4i1.21110
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Abstract

This research paper presents the study of 16 samples of deformed steel wires, which were applied to tensile tests using two types of extensometers: contact and laser. The main objective of the analysis is to determine if the results obtained by the laser extensometer have sufficient accuracy to determine the tensile mechanical properties properly, in order to validate the use if laser extensometer in standard laboratory tensile tests, as well as determine a methodology of the obtainment of the mechanical properties of steel samples with an undefined yield point. From the results, it is concluded that the laser extensometer, as well as the methodology used, produce results which are quantitative similar to the contact extensometer, therefore validating its use for standard laboratory tensile testing of materials with an undefined yield point.

https://doi.org/10.15517/mym.v4i1.21110
PDF (Español (España))

References

Abarca, A; Monge, A. Comparación de determinación de propiedades mecánicas en barras de refuerzo para concreto con extensómetro axial convencional y extensómetro láser, Revista Métodos & Materiales, pp 4 – 20. Vol 3, 2013.

ASTM A1064 / A1064M – 13. (2013). Standard Specification for Carbon-Steel Wire and Welded Wire Reinforcement, Plain and Deformed, for Concrete. ASTM International, West Conshohocken, PA, 2013, DOI: 10.1520/A1064_A1064M. www.astm.org.

ASTM A370 / A370 – 14. (2014). Standard Test Methods and Definitions for Mechanical Testing of Steel Products. ASTM International, West Conshohocken, PA, 2013, DOI: 10.1520/A0370-14. www.astm.org.

ASTM E83 / E83-10. (2010). Standard Practice for Verification and Classification of Extensometer Systems. ASTM International, West Conshohocken, PA, 2010, DOI: 10.1520/E0083-10A. www.astm.org.

Avner, S. (1988). Introducción a la metalurgia física. 2da ed. Mc Graw Hill/ Interamericana de México. D.F. México.

Gere, J. Timoshenko, S. (1986). Mecánica de Materiales. International Thomson. D.F. México.

MTS Systems Corporation. (2013) Services and Accessories Catalog. Estados Unidos. www.mts.com

MTS Systems Corporation (2009). Series LX Laser Extensometer Product Information. Manual usuario: 015-207-801 F, Estados Unidos www.mts.com

Navarro, M (2010). Probabilidad y Estadística: un enfoque teórico y práctico. Editorial Tecnológica de Costa Rica. Instituto Tecnológico de Costa Rica. Cartago. Costa Rica.

Reglamento Técnico RTCR 452:2011 Barras y Alambres de Acero de refuerzo para concreto. N° 37341-MEIC. La Gaceta Digital 11/10/2013 N°152. Recuperado de: http://www.nacion.com/archivo/Reglamento-RTCR-Alambres-Refuerzo-Concreto_LNCFIL20131119_0002.pdf

Smith, W. Hashemi, J. (2006) Fundamentos de la ciencia e Ingeniería de materiales. 4ta Ed. Mc Graw Hill. D.F. México.

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